Optimized data exploration applied to the simulation of a chemical process

Self Cite

Simulation is besides experimentation a key technology in design, analysis and operation of distillation columns. The reliability of simulations to answer questions concerning the real process strongly depends on model quality, which needs to be reliable and predictive. Usually available plant data can be used to validate and if necessary, to improve the model. In this contribution challenges and opportunities of a continuous model improvement in a flowsheet simulator with emphasis on new possibilities triggered by digitalization will be discussed.

Section: Combining Data and Modelsmentioning

confidence: 99%

Modeling, Simulation, and Optimization 4.0 for a Distillation Column

Asprion

2020

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“…Since the standard deviation directly quantifies the uncertainty about a prediction, it can be used to suggest a new simulation to improve the model. Such an approach has already been proposed, e.g., in , and is closely related to, e.g., adaptive sampling and Bayesian optimization .…”

Section: Supervised Learningmentioning

confidence: 99%

Some Aspects of Combining Data and Models in Process Engineering

Heese

Nies

Bortz

2020

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Observing phenomena under defined conditions and building mathematical models to make further predictions are essential ingredients of natural and engineering sciences. Recent technological and methodical advances make large and highdimensional simulation data accessible to model building and therefore to optimization. In this article, selected machine learning methods are highlighted and applied to example data from simple flow sheet simulations. Furthermore, the essential outcomes of the workshop dealing with combination of data and models during the Tutzing Symposium 2019 are summarized.

“…Machine‐learning methods can help to quantify the feasible domain in the design space, thus, avoiding time‐consuming manual trial‐and‐error calculations. To this end, an adaptive design‐of‐experiments scheme has been developed to run the simulations, making the method computationally efficient .…”

Section: A Preliminary Look Into Machine Learningmentioning

confidence: 99%

“…Example for the application of machine learning to solving thermodynamic tasks in process simulation : determination of the feasible operating range of a partial evaporator. a) Sketch of the evaporator; b) initial set of design points to start the exploration of the feasible range; c) – e) successive exploration of the feasible domain; f) average distance between the true and the learned boundaries separating the feasible domain (i.e., two‐phase coexistence) from the infeasible (single‐phase) domains.…”

Section: A Preliminary Look Into Machine Learningmentioning

confidence: 99%

“…In more complex situations corresponding algorithms could be more difficult to devise and their execution could suffer from convergence problems. As an example for machine learning, an adaptive exploration scheme was applied in to learn this feasible range successively from simulations. The procedure commences with a small number of initial design points, as shown in Fig.…”

Section: A Preliminary Look Into Machine Learningmentioning

confidence: 99%

See 1 more Smart Citation

Digitalization in Thermodynamics

Forte

Jirasek

Bortz

et al. 2019

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Digitalization is about data and how they are used. This has always been a key topic in applied thermodynamics. In the present work, the influence of the current wave of digitalization on thermodynamics is analyzed. Thermodynamic modeling and simulation is changing as large amounts of data of different nature and quality become easily available. The power and complexity of thermodynamic models and simulation techniques is rapidly increasing, and new routes become viable to link them to the data. Machine learning opens new perspectives, when it is suitably combined with classical thermodynamic theory. Illustrated by examples, different aspects of digitalization in thermodynamics are discussed: strengths and weaknesses as well as opportunities and threats.